Management of network elements using a proxy agent

ABSTRACT

A proxy agent for communicating data components between a Network Management System (NMS) which supports a first network management protocol, for example Simple Network Management Protocol (SNMP), and one or more network elements which support a second protocol, for example Transaction Language 1 (TL1). The proxy agent comprises a directory for storing the data components wherein each data component is associated with a first data component identifier which is compatible with the first protocol, and with a second data component identifier which is compatible with the second protocol. The directory provides an inherent mapping between protocols and obviates the need for a separate mapping component. The directory may conveniently comprise a Lightweight Directory Access Protocol (LDAP) directory.

FIELD OF THE INVENTION

The invention relates to communication between systems which supportincompatible protocols using a proxy agent. The invention relatesparticularly, but not exclusively, to the management of network elementsby a network management system.

BACKGROUND TO THE INVENTION

The Simple Network Management Protocol (SNMP) is an application layernetwork management protocol that enables management information to beexchanged between network elements (NEs) and a network management system(NMS). SNMP, which is part of the Transmission Control Protocol/InternetProtocol (TCP/IP) protocol suite, is defined in internet standard STD15, RFC 1157.

Typically, an NMS manages a plurality of network elements each of whichincludes an SNMP agent. Each network element gathers managementinformation pertaining to itself and in some cases the network aroundit. The SNMP agent makes this management information available to theNMS via SNMP.

SNMP may be used in a variety of telecommunication networks, or datacommunication networks, including Local Area Networks (LANs) or WideArea Networks (WANs). Network elements, which are sometimes callednetwork nodes or managed devices, may take a wide variety of formsincluding routers, access servers, hubs, computer hosts, printers,switches or bridges.

In some cases, an SNMP NMS may be required to manage network elementsthat do not support SNMP. In such cases a proxy agent, or proxy, isprovided to mediate between the SNMP NMS and a non-SNMP network element.Conventionally, a respective proxy is devised for each type of non-SNMPnetwork element. Such proxys are considered to be inflexible since theyare configured specifically for a particular type of network element. Asa result, conventional proxys cannot readily support changes in thenetwork element, additional management features or changes to theManagement Information Base (MIB) which stores the gathered managementinformation.

It would be desirable, therefore, to provide a more flexible proxyagent.

SUMMARY OF THE INVENTION

Accordingly, a first aspect of the invention provides a proxy agent forcommunicating data components between a first system which supports afirst protocol and a second system which supports a second protocol,said first and second protocols being mutually incompatible, the proxyagent comprising a directory for storing said data components whereineach data component stored in said directory is associated with a firstdata component identifier which is compatible with said first protocol,and with a second data component identifier which is compatible withsaid second protocol.

The directory provides an inherent mapping between protocols andobviates the need for a separate mapping component.

In one embodiment, the proxy agent includes a first protocol handlerarranged to communicate with said first system using said firstprotocol, and a second protocol handler arranged to communicate withsaid second system using said second protocol, wherein said firstprotocol handler is arranged to send data components to, and/or receivedata components from, said directory using said first data componentidentifier, and said second protocol handler is arranged to send datacomponents to, and/or receive data components from, said directory usingsaid second data component identifier.

The first and second protocol may each comprise a respective networkmanagement protocol. For example, said first protocol may compriseSimple Network Management Protocol (SNMP). The second protocol maycomprise Transaction Language 1 (TL1).

In a typical embodiment, said first system comprises a NetworkManagement system (NMS) and said second system comprises a networkelement.

Conveniently, said directory comprises a directory which supportsLightweight Directory Access Protocol (LDAP).

A second aspect of the invention provides a network comprising a firstsystem which supports a first protocol and a second system whichsupports a second protocol, said first and second protocols beingmutually incompatible, and a proxy agent of the first aspect of theinvention.

A third aspect of the invention provides a method of communicating datacomponents between said first system which supports a first protocol anda second system which supports a second protocol, said first and secondprotocols being mutually incompatible, said method comprising storingsaid data components in a directory wherein each data component storedin said directory is associated with a first data component identifierwhich is compatible with said first protocol, and with a second datacomponent identifier which is compatible with said second protocol.

A fourth aspect of the invention provides a computer program productcomprising computer program code for causing a computer to perform themethod of the third aspect of the invention.

Other preferred, but not essential, features of the invention arerecited in the dependent claims.

Further advantageous aspects of the invention will become apparent tothose ordinarily skilled in the art upon review of the followingdescription of a specific embodiment of the invention and with referenceto the accompanying drawings.

The preferred features as described herein above or as described by thedependent claims filed herewith may be combined as appropriate, and maybe combined with any of the aspects of the invention as described hereinabove or by the independent claims filed herewith, as would be apparentto those skilled in the art.

It is noted that the term ‘protocol’ is often used to refer to a set ofone or more protocols. It will be understood, therefore, that the term‘protocol’ as used herein is intended to embrace ‘set of one or moreprotocols’.

BRIEF DESCRIPTION OF THE DRAWINGS

An embodiment of the invention is now described by way of example andwith reference to the accompanying drawings in which:

FIG. 1 presents a block diagram of part of a telecommunications networkincluding a conventional proxy agent;

FIG. 2 presents a schematic representation of part of a MIB hierarchy;

FIG. 3 presents a schematic representation of management informationhaving a flat or linear structure;

FIG. 4 presents a block diagram of part of a telecommunications networkincluding a proxy agent embodying one aspect of the present invention;and

FIGS. 5A and 5B present a schematic representation of directory entitiesfor use with the proxy agent of FIG. 4.

DETAILED DESCRIPTION OF THE DRAWINGS

Referring now to FIG. 1 of the drawings, there is shown, generallyindicated as 10, part of a telecommunications network. The network 10includes a network management system (NMS) 12, which supports a firstnetwork management protocol, and one or more network elements (only oneshown) 14 which support a second network management protocol (but notthe first network management protocol). A typical network comprises oneor more NMS managing a respective plurality of network elements, atleast some of which may support a management protocol other than themanagement protocol supported by the NMS.

In the present example, it is assumed that the first network managementprotocol comprises SNMP. By way of example only, the second networkmanagement protocol is assumed to comprise Transaction Language 1 (TL1)as defined by Telcordia (formerly Bellcore). TL1 is commonly supportedby the network elements of a synchronous transmission network such as aSynchronous Digital Hierarchy (SDH) network or a Synchronous OpticalNetwork (SONET) network. Hence, a typical telecommunications network maycomprise a plurality of LANs interconnected by one or more WAN, whereinthe LANs comprise TCP/IP networks and hence support SNMP, while theWAN(s) comprise a SONET/SDH network supporting TL1. One or more NMS inthe LANs may therefore need to be able to communicate with one or morenetwork element of the WAN(s).

In order that the network element 14 may be managed by the NMS 12, aproxy agent, or proxy 16, is provided. A typical conventional proxy 16comprises a respective component, or agent, for handling the first andsecond management protocols respectively. In the example of FIG. 1, theproxy 16 includes an SNMP agent, or protocol handler 18 and a native (inthis example TL1) agent or protocol handler 20. The SNMP protocolhandler 18, which typically comprises a software process, is arranged tocommunicate with the NMS via SNMP and in particular to respond to SNMPcommands received from the NMS 12. The native protocol handler 20, whichtypically comprises a software process, is arranged for communicationwith its respective non-SNMP network element 14 using, in the presentexample, TL1.

The proxy 16 further includes a mapping component 22, which typicallycomprises a software process, which translates, or maps, data (e.g.comprising commands or responses) from the format of one networkmanagement protocol into a format compatible with the other networkmanagement protocol. The mapping component 22 uses mapping definitionsto determine how data should be translated from one protocol format tothe other. In the event of a change in functionality of the NMS or thenetwork element 14, one or more new mapping definitions 24 are providedto the mapping component 22.

In some instances, the mapping component 22 may perform the requiredmapping in real-time. For example, if the mapping component 22 receivesan SNMP GET-(or read) request from the SNMP protocol handler 18, ittranslates the request into a corresponding TL1 format using apre-defined mapping definition. The resultant TL1 command is then sentto the network element 14 via the native protocol handler 20. Thenetwork element 14 responds to the native protocol handler 20 using TL1.The TL1 response is provided to the mapping component 22 whereupon themapping component 22 translates the TL1 response into an SNMP compatibleformat using an appropriate mapping definition. The translated SNMPresponse is then provided to the NMS via the SNMP protocol handler 18.The proxy 16 is not always required to operate in real time and so,optionally, includes a cache memory 26 for storing translated data. Themapping component 22 retrieves the appropriate translated data whenrequired by the NMS 12 or the network element 14.

The NMS 12 maintains a collection of information, or a database,commonly known as a Management Information Base (MIB) 13. The MIB 13holds all of the management information gathered by the NMS 12. When anew network element is added to the network managed by the NMS 12, arespective MIB definition file 28 containing management informationpertaining to the new network element is provided to the NMS 12 in orderthat the MIB 13 may be updated. An SNMP NMS 12 maintains an SNMP MIB andcan access data in the SNMP MIB using SNMP commands.

A schematic representation of an SNMP MIB is shown in FIG. 2, generallyindicated as 30. The SNMP MIB 30 exhibits a hierarchical, or tree-like,structure (typically with a nameless root) in which a plurality ofmanaged objects are arranged hierarchically and each identified by arespective object identifier (OID). In FIG. 2, the managed objects arerepresented by the nodes of the tree structure and the OIDs arerepresented by the node labels 1, 1.1, 1.2, 1.3 and so on. The hierarchy30 may be said to comprise a plurality of branches, each branchcomprising one or more nodes. The first branch (which comprises nodes1.1, 1.2 and 1.3 and forms the first level in the hierarchy) stems froma (typically unnamed) root node 31. The next level in the hierarchycomprises one or more branches (three shown in FIG. 2) stemming from oneor other of the nodes of the first branch, and so on. A managed object,or MIB object, comprises data representing a characteristic or attributeof a network element managed by the NMS. Each managed object is uniquelyidentified by a respective OID. Hence, an SNMP MIB provides ahierarchical, or tree-like, model of a managed network. To be compatiblewith the SNMP MIB hierarchical structure, data stored in the SNMP MIBmust exhibit a compatible hierarchical structure. SNMP may therefore besaid to support a hierarchical, or tree-like, data structure.

In contrast, other network management protocols support non-hierarchicaldata structures. For example, TL1 supports a flat, or linear, datastructure. FIG. 3 provides a schematic representation of managementinformation 40 exhibiting a flat or linear data structure. Themanagement information 40 comprises, by way of example only, five datacomponents 42<Data_(—)1>, <Data_(—)2>, <Data_(—)3>, <Data_(—)4>and<Data_(—)5>arranged in a linear fashion. Each data component 42 may, forexample, represent a respective characteristic of a network element, ora characteristic of an aspect of the network element. Each datacomponent 42 is associated with a respective data identifier 44Data_ID_(—)1, Data_ID_(—)2, Data_ID_(—)3, Data_ID_(—)4 and Data_ID_(—)5.

Referring again to FIG. 1, one of the tasks of the mapping component 22is to receive data from the network element 14, via the native-protocolhandler 20, in a linear data structure and to map, or associate, eachdata component 42 to a respective OID in accordance with a mappingdefinition. As a result, the data components 42 are compatible with ahierarchical data structure and therefore with SNMP. The mappingcomponent 22 may then store the data components 42 and respective OIDsin the cache 26 and/or provide them to the NMS 12 via the SNMP protocolhandler 18.

The operation of the mapping component 22 is relatively inflexible as itis dependant on a plurality of pre-defined mapping definitions. As aresult, the proxy 16 is closely coupled to the network element 14 (ortype of network element) with which it is associated. A respectiveseparate proxy, and more particularly a respective separate mappingcomponent, is required for each different type of network element (i.e.network elements which share common mapping definitions).

FIG. 4 presents a block diagram of part of a telecommunications network110 comprising a network management system 112, one or more networkelements 114 (two shown in FIG. 4) and a proxy agent, or proxy 150embodying one aspect of the invention. The network 110 is generallysimilar to the network 10 and similar numerals are used to denotesimilar components. In particular, the NMS 112 is assumed by way ofexample to comprise an SNMP NMS and the network elements 114 are assumedto support a non-SNMP network management protocol, namely TL1.Accordingly, The native protocol handlers 120 support TL1, while theprotocol handler 118 communicating with the NMS 112 supports SNMP.

However, unlike proxy 16, proxy 150 does not comprise a mappingcomponent operating on pre-defined mapping definitions. Rather, proxy150 includes, or is associated with, a memory, or other storage means,in which the proxy 150 maintains a directory 152, or other collection ofdata, which inherently provides mapping functionality. In the embodimentof FIG. 4, the directory 152—which may be referred to as a networkdirectory—is held in a cache memory, although other convenient storagedevices may alternatively be used.

FIGS. 5A and 5B present schematic representations of a respectivedirectory object or entity 154. Each directory entity comprises one ormore directory entries 156. Each directory entry 156 comprises arespective data component 158, and at least two associated respectivedata component identifiers 160, 162. Each directory entity 154 is alsoassociated with a respective entity identifier 164 which itself isassociated with a respective data component 166.

At least one of the data component identifiers 160, 162 uniquelyidentifies the respective directory entry 156 within the directory 152.In the following description, it is assumed that the data componentidentifiers 160 provide this unique identification. Preferably, eachdata component identifier 160 comprises a respective hierarchical uniqueidentifier, preferably an SNMP OID. Hence, the preferred directory 152arranges its directory entries 156 in a hierarchical, or tree-like,manner. As a result, each directory entry 156 can be accessed usingSNMP, or a similar hierarchical protocol. In the preferred embodiment,each entity identifier 164 also comprises a respective SNMP OID whichcorresponds with one hierarchical level above the SNMP OIDs of the datacomponent identifiers 160. The corresponding data component 166typically comprises a name, type or class of entity.

Hence, in the preferred embodiment, all of the directory entries 156 ofa directory entity 154 share a common hierarchical level and share acommon path to the root of the hierarchy, i.e. the directory entries 156are grouped into entities 156 according to their respective positions ina hierarchy. Conveniently, the hierarchy corresponds with the hierarchyexhibited by the MIB maintained by the NMS. In the present example, thehierarchy exhibited by the directory 152 corresponds with the hierarchyof the SNMP MIB 113 maintained by the NMS 112. In the preferredembodiment, the directory 152 comprises at least one respective dataentity 154 for each branch of the hierarchy.

The structure of each data entity 154 is determined by a respectiveentity template, or schema 151, which provides data fields for theentity identifier 164, data components 158, 166 and data componentidentifiers 160, 162 for each data entry 156. The entity structureprovided for by a respective schema 151 corresponds with the structureof the respective hierarchical branch of the directory 152 that theresultant entity 154 is required to represent which, in turn, isdetermined by the characteristics of the corresponding network element,type or aspect of network element.

One or more respective schema 151 is created for each network element,or each type of network element. Each schema 151 is created with arespective OID, in particular a respective SNMP OID, assigned to each ofits data component identifiers 160. In addition, a correspondingrespective name, label or other identifier (typically in the form of avalue or string) is assigned to each data component identifier 162 in aform that is compatible with the network management protocol supportedby the network elements 114 (TL1 in this example). The correspondencebetween SNMP OIDs for use as data component identifiers 160 and TL1identifiers for use as data component identifiers 162 may readily bederived from the information carried by the respective MIB definition(s)for each network element 114. Further, a respective OID, in particular arespective SNMP OID, is assigned to the entity identifier 164. The datacomponent 166 corresponding to the entity identifier 164 is assigned arespective name, label or other identifier (typically in the form of avalue or string) in a form that is compatible with the networkmanagement protocol supported by the network elements 114 (TL1 in thisexample). As a result, each entity 154 is identifiable by networkelements 114 that support TL1 (by means of the data component 166) andby the NMS 112 and network elements that support SNMP (by means of theentity identifier 164).

The or each native protocol handler 120 is arranged to cause one or moredirectory entities 154 to be populated with the data it receives fromthe respective network element 114. More particularly, the or eachnative protocol handler 114 causes the respective data component 158fields to be populated. The data component 158 fields are populated withcorresponding data components 158 received from the respective networkelement 114. As a result, each data component 158 in a directory entity154 is associated with a first identifier 162, which is compatible withthe network management protocol supported by the respective networkelement 114 (e.g. TL1), and a second identifier 160, which is compatiblewith the network management protocol supported by the NMS 112 (e.g.SNMP). Once the schema 151 is populated, it becomes an entity 154 withinthe directory 152.

For a given set of data components received from a network element 114,the native protocol handler 120 determines which schema 151 to populateby means of the data component 166 associated with the entity identifier164.

By way of example, assume that a network element 114 provides managementinformation to the native protocol handler 120 according to the datastructure shown in FIG. 3, i.e. five data components 42<Data_(—)1>to<Data_(—)5>each having a respective data identifier 44 Data_ID_(—)1 toData_ID_(—)5. It is assumed that the NMS 112 has created a respectivemanaged object, or node, in the MIB hierarchy in respect of each of thefive data components 42 with respective OIDs 1.3.4.1, 1.3.4.2, 1.3.4.3,1.3.4.4 and 1.3.4.5 (see FIG. 2). Accordingly, a respective schema 151is created with the structure exhibited by the entity 154 of FIG. 5B.Each OID is assigned to a respective data component identifier 160 fieldas shown in FIG. 5B. Each data identifier 44 Data_ID_(—)1 toData_ID_(—)5 is assigned to a respective data component identifier 162field as shown in FIG. 5B. The OID 3.1.4 is assigned to the entityidentifier 164 field and data (String_(—)1 in this example) is assignedto the data component 166.

A respective management information identifier (not shown) is associatedwith each set of management information 40 that is produced by a networkelement 114. In the preferred embodiment, the data assigned to the datacomponent 166 comprises the management information identifier used bythe network element 114. In the present example, the managementinformation identifier is assumed to comprise a data string,String_(—)1. String_(—)1 takes a form which is compatible with thenetwork management protocol supported by the native protocol handler 120and may thus be used by the native protocol handler 120 to identify theappropriate schema 151 into which the management information 40 shouldbe written.

Hence, when the native protocol handler 120 receives managementinformation 40 from the network element 114, it causes the managementinformation 40 to be written into the schema 151 identified by the sameidentifier, in this case String_(—)1, with which the managementinformation 40 itself is associated. The data component identifiers 162(each of which corresponds with a respective data identifier 44 of themanagement information 40) are used to determine into which respectivedata component 158 field each data component 42 of the managementinformation 40 is written. In the preferred embodiment, the nativeprotocol handler 120 arranges to management information 40 into a formwhere each data component 42 comprises a value or string assigned to arespective data identifier 44 and sends the paired information to thedirectory 152, or more particularly, to the module or process (notshown) that manages the reading and writing of data to and from thedirectory 152. The data components 42 are written to the appropriatedata component 158 filed by matching the respective data identifiers 44with the data component identifiers 162.

It is noted that the same schema 151 may be used in respect of differentnetwork elements, or aspects of network elements, which are of the sametype with the result that more than one entity 154 having the same OIDs160 may exist in the directory 152. Such entities may be distinguishedfrom one another by means of a unique identifier, e.g. an identifierunique to the respective network element, included in the managementinformation provided by the network element and therefore also includedin the schema 151, typically as the first of the data components 158.

The SNMP protocol handler 118 may retrieve or receive data components158 from a respective entity 154 in the directory 152 using SNMP sinceeach data component 158 is associated with a respective SNMP OID 160.For example, the SNMP protocol handler 118 may be arranged to access thedirectory 152 using an SNMP GET (or read) command specifying aparticular SNMP OID 160 and the data component 158 corresponding to theSNMP OID 160 is returned. In cases where the are more than one instancesof the respective entity 154, a respective data component 158corresponding to the same SNMP OID 160 may be returned in respect ofeach instance.

The preferred hierarchical structure of the directory 152 also allowsdata to be retrieved from the directory 152 using bulk SNMP GET (read)commands. For example, with reference to FIGS. 5A and 5B, a simple SNMPGET command directed to OID 1.3.4 returns the data value String_(—)1.This information may be obtained either from the data entry for 1.3.4 ofthe (or each) entity 1.3 (FIG. 5A) or from the value assigned to theentity identifier 164 of entity 1.3.4. However, should a bulk SNMP GETcommand request all data components whose OID comprises the stem 1.3.4,this may conveniently be performed by returning all of the datacomponents 158 from the (or each) entity 1.3.4.

Alternatively, the data components may be provided to the SNMP protocolhandler 118 using an SNMP TRAP command. Typically, a directorymanagement module (not shown), usually in the form of a softwareprocess, is associated with the directory 152 for managing read andwrite operations from and to the directory 152. The directory managementmodule may be arranged to detect updates to the directory 152 and tocommunicate the updated information, i.e. update data components 158 andassociated OIDs, to the SNMP protocol handler 118 using an SNMP TRAPcommand.

All of the information received by the SNMP protocol handler 118 may becommunicated to the NMS 112 using SNMP in conventional manner in orderthat the MIB 113 may be maintained.

In the preferred embodiment, the directory 152 comprises an LDAP(Lightweight Directory Access Protocol) directory, i.e. a directory thatsupports LDAP. LDAP is a directory access protocol defined in standardRFC 1777. Each entry in an LDAP directory may comprise one or more datacomponents and is associated with a first name (usually referred to as adistinguished name) which uniquely identifies the directory entry, and asecond name (usually referred to as a type). Moreover, LDAP directoryentries are arranged in a hierarchical structure comparable to thestructure described above in respect of directory 152. Hence, an LDAPdirectory may readily be used to provide the directory 152, wherein thedistinguished name of each directory entry may be used to provide theOID 160 and the second name (or type) may be used to provide the datacomponent identifiers 162. Accordingly, LDAP schemas may be used toprovide the schemas for the directory entities 154 described above.Conveniently, conventional LDAP schemas, upon creation, are alreadyassociated with positions in the MIB hierarchy.

Hence, in the preferred embodiment, MIB definition files 128 are used tocreate one or more corresponding LDAP schema 151 which, when populatedby data received from a network element, provide directory entitieswhich are stored in an LDAP directory. Because of the dual naming, oridentifier, facility afforded by LDAP directory entries, the LDAPdirectory serves not only as a cache memory for management information,but also as a means for providing convenient mapping between twodifferent network management protocols.

More generally, the directory 152 inherently provides a mapping betweentwo different network management protocols (SNMP and TL1 in the presentexample) because each data component 158 is associated with twoidentifiers 160, 162, one being compatible with one network managementprotocol and the other being compatible with the other networkmanagement protocol. In addition, the directory 152 provides thefunction of the cache memory 26 (FIG. 1). The proxy 150 does nottherefore require a mapping component similar to that described withreference to FIG. 1.

As a result, the proxy 150 is relatively flexible and may support notonly more than network element but also more than one type of networkelement (i.e. network elements that provide different types orstructures of management information)—a respective MIB definition file128 is provided to the NMS 112 in respect of each type of networkelement 114 from which appropriate schemas are generated. Once theappropriate schemas are generated, the respective types of networkelement 114 can be managed by the NMS in the manner described above.Similarly, the proxy 150 readily supports modifications or updates tonetwork elements, or any other changes which result in a new or modifiedMIB 113.

The foregoing description primarily describes communication ofmanagement information from the network elements 114 to the NMS 112 viathe directory 152. It will be understood however that communication ofmanagement information between the network elements 114 and the NMS 112may be bi-directional. The dual naming characteristic of the directory152 readily allows both the NMS 112 and the network elements 114 to sendinformation to and receive information from the directory 152.

It will further be understood that the invention is not limited tonetworks in which only two different types of network managementprotocols are used. The embodiment may readily be extend to supportthree or more otherwise incompatible network management protocols byproviding a respective data component identifier in each directoryentity for each network management protocol to be supported.

The invention is not limited to the network management protocols SNMPand/or TL1. Moreover, the invention may be used with protocols otherthan network management protocols. Further, the invention is not limitedto communication between an NMS and one or more network element—theinvention also has application between network elements supportingdifferent protocols. In general, the invention may be applied wherecommunication is required between two or more systems or devices whichsupport different, or incompatible, protocols, or do not at leastsupport one suitable protocol in common.

The invention is not limited to the embodiment described herein whichmay be modified or varied without departing from the scope of theinvention.

1. A proxy agent for communicating data components between a firstsystem which supports a first protocol and a second system whichsupports a second protocol, said first and second protocols beingmutually incompatible, the proxy agent comprising a directory forstoring said data components wherein each data component stored in saiddirectory is associated with a first data component identifier which iscompatible with said first protocol, and with a second data componentidentifier which is compatible with said second protocol.
 2. A proxyagent as claimed in claim 1, further including a first protocol handlerarranged to communicate with said first system using said firstprotocol, and a second protocol handler arranged to communicate withsaid second system using said second protocol, wherein said firstprotocol handler is arranged to send data components to, and/or receivedata components from, said directory using said first data componentidentifier, and said second protocol handler is arranged to send datacomponents to, and/or receive data components from, said directory usingsaid second data component identifier.
 3. A proxy agent as claimed inclaim 1, in which the directory supports a hierarchical data structurein which each stored data component is associated with a respectiveposition in the hierarchical data structure.
 4. A proxy agent as claimedin claim 3, wherein said respective first data component identifierssupport a hierarchical structure and serve to identify the respectiveposition of the respective data component in the hierarchical datastructure.
 5. A proxy agent as claimed in claim 4, wherein said datacomponents are arranged into directory entities within the directory,each directory entity comprising a one or more directory entries, eachdirectory entry comprising a respective data component, a respectivefirst data component identifier and a respective second data componentidentifier.
 6. A proxy agent as claimed in claim 5, wherein each datacomponent within a directory entity belongs to the same branch of thehierarchical data structure.
 7. A proxy agent as claimed in claim 5,wherein each directory entity is associated with a first directoryentity identifier which is compatible with said first protocol and witha second identifier which is compatible with said second protocol.
 8. Aproxy agent as claimed in claim 7, in which said respective firstdirectory entity identifiers support a hierarchical structure.
 9. Aproxy agent as claimed in claim 7, in which each of said first directoryentity identifiers belongs to a branch of the hierarchical datastructure that is one hierarchical level above the branch to which therespective data components in the respective directory entity belong.10. A proxy agent as claimed in claim 5, in which a respective schema isprovided to define each type of directory entity and wherein arespective directory entry is created by populating a respective schemawith one or more data components.
 11. A proxy agent as claimed in claim1, wherein said first protocol supports a hierarchical data structure.12. A proxy agent as claimed in claim 1, wherein said first and secondprotocol each comprise a respective network management protocol.
 13. Aproxy agent as claimed in claim 1, wherein said first protocol comprisesSimple Network Management Protocol (SNMP).
 14. A proxy agent as claimedin claim 1, wherein said first system comprises a Network Managementsystem (NMS) and said second system comprises a network element.
 15. Aproxy agent as claimed in claim 14, wherein said proxy agent effectscommunication between said Network Management system and a plurality ofnetwork elements, at least some of said network elements supporting saidsecond protocol.
 16. A proxy agent as claimed in claim 1, wherein saiddirectory comprises a directory which supports Lightweight DirectoryAccess Protocol (LDAP).
 17. A network comprising a first system whichsupports a first protocol and a second system which supports a secondprotocol, said first and second protocols being mutually incompatible,and a proxy agent as claimed in claim
 1. 18. A method of communicatingdata components between said first system which supports a firstprotocol and a second system which supports a second protocol, saidfirst and second protocols being mutually incompatible, said methodcomprising storing said data components in a directory wherein each datacomponent stored in said directory is associated with a first datacomponent identifier which is compatible with said first protocol, andwith a second data component identifier which is compatible with saidsecond protocol.
 19. A computer program product comprising computerprogram code for causing a computer to perform the method of claim 18.